/*
 * Copyright (C) 2020 Open Source Robotics Foundation
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 *
 */
#ifndef GZ_SIM_SYSTEMS_BUOYANCY_HH_
#define GZ_SIM_SYSTEMS_BUOYANCY_HH_

#include <gz/sim/System.hh>
#include <memory>

namespace gz
{
namespace sim
{
// Inline bracket to help doxygen filtering.
inline namespace GZ_SIM_VERSION_NAMESPACE {
namespace systems
{
  // Forward declaration
  class BuoyancyPrivate;

  /// \brief A system that simulates buoyancy of objects immersed in fluid.
  /// All SDF parameters are optional. This system must be attached to the
  /// world and this system will apply buoyancy to all links that have collision
  /// shapes.
  ///
  /// The volume and center of volume will be computed for each link, and
  /// stored as components. During each iteration, Archimedes' principle is
  /// applied to each link with a volume and center of volume component.
  ///
  /// Plane shapes are not handled by this plugin, and will not be affected
  /// by buoyancy.
  ///
  /// ## System Parameters
  ///
  /// * `<uniform_fluid_density>` sets the density of the fluid that surrounds
  /// the buoyant object. [Units: kgm^-3]
  /// * `<graded_buoyancy>` allows you to define a world where the buoyancy
  /// changes along the Z axis. An example of such a world could be if we are
  /// simulating an open ocean with its surface and under water behaviour. This
  /// mode slices the volume of each collision mesh according to where the water
  /// line is set. When defining a `<graded_buoyancy>` tag, one must also define
  /// `<default_density>` and `<density_change>` tags.
  /// * `<default_density>` is the default fluid which the world should be
  /// filled with. [Units: kgm^-3]
  /// * `<density_change>` allows you to define a new layer.
  /// * `<above_depth>` a child property of `<density_change>`. This determines
  /// the height at which the next fluid layer should start. [Units: m]
  /// * `<density>` the density of the fluid in this layer. [Units: kgm^-3]
  /// * `<enable>` used to indicate which models will have buoyancy.
  /// Add one enable element per model or link. This element accepts names
  /// scoped from the top level model (i.e. `<model>::<nested_model>::<link>`).
  /// If there are no enabled entities, all models in simulation will be
  /// affected by buoyancy.
  ///
  /// ## Examples
  ///
  /// ### uniform_fluid_density world
  ///
  /// The `buoyancy.sdf` SDF file contains three submarines. The first
  /// submarine is neutrally buoyant, the second sinks, and the third
  /// floats. To run:
  ///
  /// ```
  /// gz sim -v 4 buoyancy.sdf
  /// ```
  ///
  /// ### graded_buoyancy world
  ///
  /// Often when simulating a maritime environment one may need to simulate both
  /// surface and underwater vessels. This means the buoyancy plugin needs to
  /// take into account two different fluids. One being water with a density of
  /// 1000kgm^-3 and another being air with a very light density of say 1kgm^-3.
  /// An example for such a configuration may be found in the
  /// `graded_buoyancy.sdf` world.
  ///
  /// ```
  /// gz sim -v 4 graded_buoyancy.sdf
  /// ```
  ///
  /// You should be able to see a sphere bobbing up and down undergoing simple
  /// harmonic motion on the surface of the fluid (this is expected behaviour
  /// as the SHM is usually damped by the hydrodynamic forces. See the hydro-
  /// dynamics plugin for an example of how to use it). The key part of this is
  ///
  /// ```
  /// <graded_buoyancy>
  ///   <default_density>1000</default_density>
  ///   <density_change>
  ///     <above_depth>0</above_depth>
  ///     <density>1</density>
  ///   </density_change>
  /// </graded_buoyancy>
  /// ```
  /// The default density tag says that by default the world has a fluid density
  /// of 1000kgm^-3. This essentially states that by default the world is filled
  /// with dihydrogen monoxide (aka water). The `<density_change>` tag
  /// essentially establishes the fact that there is a nother fluid. The
  /// `<above_depth>` tag says that above z=0 there is another fluid with a
  /// different density. The density of that fluid is defined by the `<density>`
  /// tag. We will be simulating air with a fluid density of 1kgm^-3.
  class Buoyancy
      : public System,
        public ISystemConfigure,
        public ISystemPreUpdate,
        public ISystemPostUpdate
  {
    /// \brief Constructor
    public: Buoyancy();

    /// \brief Destructor
    public: ~Buoyancy() override = default;

    // Documentation inherited
    public: void Configure(const Entity &_entity,
                           const std::shared_ptr<const sdf::Element> &_sdf,
                           EntityComponentManager &_ecm,
                           EventManager &_eventMgr) override;

    // Documentation inherited
    public: void PreUpdate(
                const UpdateInfo &_info,
                EntityComponentManager &_ecm) override;

    // Documentation inherited
    public: void PostUpdate(
                const UpdateInfo &_info,
                const EntityComponentManager &_ecm) override;

    /// \brief Check if an entity is enabled or not.
    /// \param[in] _entity Target entity
    /// \param[in] _ecm Entity component manager
    /// \return True if buoyancy should be applied.
    public: bool IsEnabled(Entity _entity,
        const EntityComponentManager &_ecm) const;

    /// \brief Private data pointer
    private: std::unique_ptr<BuoyancyPrivate> dataPtr;
  };
  }
}
}
}

#endif
